超薄介质插层调制的氧化铟锡/锗肖特基光电探测器

本文通过在氧化铟锡(indium tin oxide, ITO)透明电极和锗(germanium, Ge)之间引入超薄氧化物介质层以调节其接触势垒高度,制备出低暗电流、高响应度的锗肖特基光电探测器.比较研究了采用不同种类介质Al_2O_3和MoO_3,以及不同掺杂浓度的锗和硅衬底上外延锗材料制作的ITO/Ge肖特基二极管特性.发现2 nm厚的Al_2O_3插层可有效提高ITO与n-Ge和i-Ge的接触势垒高度,而MoO_3插层对ITO与不同Ge材料的接触势垒高度影响不明显. ITO/Al_2O_3/i-Ge探测器由于其增大的势垒高度表现出性能最佳,暗电流(–4 V)密度低至5.91 mA/cm~2, 1310 nm波长处光响应度高达4.11 A/W.而基于硅基外延锗(500 nm)材料制作的ITO/Al_2O_3/Ge-epi光电探测器的暗电流(–4 V)密度为226.70 mA/cm~2, 1310 nm处光响应度为0.38 A/W.最后,使用二维位移平台对ITO/Al_2O_3/i-Ge光电探测器进行了单点成像实验,在1310 nm, 1550 nm两个波段得到了清晰可辨的二维成像图.     

二维WSe2场效应晶体管光电性能

自石墨烯被发现以来,随着人们不断的研究和探索,越来越多具有类似结构的二维材料因其优异的光电性质相继被发现和研究。过渡金属硫族化合物(TMDs)因其丰富的物理性质而受到广泛关注。本文研究了三层二硒化钨(WSe_2)纳米片的光电性能。利用范德华力将WSe_2转移到SiO_2/Si衬底的Au电极上,用银浆引出背栅电极,制备了WSe_2场效应晶体管,其载流子迁移率为3.42 cm~2/(V·s)。WSe_2场效应晶体管在630 nm波长下探测器响应度为0.61 A/W,器件的光响应恢复时间为1 900 ms。     

PECVD法制备高结晶GaN薄膜及其光电响应性能

采用一种简单、绿色、低成本的等离子增强化学气相沉积(PECVD)法,在950℃下成功制备了高结晶质量的GaN薄膜.为了提高GaN薄膜结晶质量和弄清GaN薄膜光响应机制,研究了GaN缓冲层制备温度对GaN薄膜结晶质量和光电性能的影响.研究表明,随着GaN缓冲层制备温度的增加,GaN薄膜的结晶质量先提高后降低,在缓冲层温度为875℃时,结晶质量最高,此时计算得出的总位错密度为9.74×10~9 cm^-2,载流子迁移率为0.713 cm~2/(V·s).经过退火后,GaN薄膜的总位错密度降低到7.38×10~9 cm^-2,载流子迁移率增大到43.5 cm~2(V·s),此时GaN薄膜光响应度为0.20 A/W,光响应时间为15.4 s,恢复时间为24 s,可应用于紫外光探测器.通过Hall测试和X射线光电子能谱仪分析得出,GaN薄膜内部存在着N空位、Ga空位或O掺杂,它们作为深阱能级束缚和复合光生电子和空穴,使得光响应度与偏压呈抛物线关系;另外,空位和O掺杂形成的深阱能级也是导致GaN薄膜的光电流响应和恢复缓慢的根本原因.     

基于并五苯/酞菁铅异质结的近红外光敏有机场效应管(英文)

采用并五苯(Pentacene)和酞菁铅(PbPc)两种有机材料作为有源层,制备了异质结有机光敏场效应管。在波长为808 nm、强度为124 mW/cm2的近红外光照条件下,异质结phOFET获得最大的光暗电流比达4.4×104,栅压为-50 V时的最大光响应度为118 mA/W,比单层酞菁铅phOFET分别高出766倍和785倍。在经过120 h后,器件的最大光暗电流比和最大光响应度分别稳定于5.4×104和326 mA/W附近。由于在异质结phOFET中采用了对近红外光具有高吸收效率的酞菁铅作为光敏层,而高空穴迁移率的并五苯材料作为靠近栅介质的沟道层,光生载流子的产生与传输能力得到了有效的提高。实验结果表明,基于并五苯/酞菁铅的有机异质结应用于光敏有机场效应管的结构设计中,可以使phOFET成为一种同时具有良好光敏性及稳定性的近红外光探测器件。     

衬底加热和电极修饰对提高有机场效应晶体管性能的影响

通过衬底加热和氧化钼(MoO3)修饰源漏极制备了并五苯有机场效应晶体管.研究了衬底温度和电极修饰层厚度对器件性能的影响.实验结果表明:当衬底温度为60℃、MoO3修饰层为10 nm时,器件性能获得了显著增强,场效应迁移率由原来的3.39×10-3 cm2/(V·s)提高到2.25 ×10-1 cm2/(V·s),阈值电压由12 V降低到3V.器件性能的改善归因于:衬底加热可以优化有源层形貌,改善载流子传输;而MoO3修饰层显著降低了电极与有源层之间的接触势垒,提高了载流子的注入.因此,衬底加热与电极修饰对于制备高性能有机场效应晶体管是不可或缺的优化手段.     

柔性有机电致发光器件导电基板的工艺性能

在聚对苯二甲酸乙二醇酯(PET)柔性衬底上采用直流磁控溅射技术制备了氧化铟锡(ITO)透明导电薄膜,研究了衬底温度、溅射功率和溅射压强等工艺条件对薄膜光电性能的影响,并利用原子力显微镜(AFM)表征了衬底及ITO薄膜的表面形貌。结果表明,在PET衬底温度50℃、溅射功率100W和溅射压强2.66×10-1Pa的条件下,可以得到低方阻(50Ω/□)和高透过率(>90%)的透明导电薄膜。以此柔性ITO衬底为阳极,制备了结构为PET/ITO/NPB/Alq3/Mg∶Ag的柔性有机电致发光器件,在驱动电压为13V时,器件的发光亮度达到了2834cd/m2。     

基于小分子半导体IEICO的高性能倍增型有机光电探测器

采用溶液法制备了结构为ITO/ZnO/P3HT∶IEICO/Al和ITO/PEDOT∶PSS/P3HT∶IEICO/Al的倍增型有机光电探测器,活性层中电子给体(P3HT)和电子受体(IEICO)的质量比为100∶1。以氧化锌(ZnO)为界面层的器件在正向与反向偏压下都能良好工作,而以PEDOT∶PSS为界面层的器件只能在反向偏压下工作。-15 V偏压下,与PEDOT∶PSS界面层器件相比, ZnO界面层器件的暗电流密度(2.2μA/cm~2)降低4倍以上,1.5 mW/cm~2光照下的光电流密度(3.7 mA/cm~2)提高3倍以上,外量子效率(External quantum efficiency,EQE)平均值(3262%)、响应度平均值(13.3 A/W)和探测灵敏度平均值(1.6×10~(13) Jones)分别提高4倍、4倍和11倍以上。这些结果表明,以ZnO为倍增型有机光电探测器的界面层,可以降低器件的暗电流密度并提高器件的EQEs,从而显著提高器件的光电性能。     

高性能SOI基GePIN波导光电探测器的制备及特性研究

本文报道了在SOI衬底上外延高质量单晶Ge薄膜并制备高性能不同尺寸Ge PIN波导光电探测器.通过采用原子力显微镜、X射线衍射、拉曼散射光谱表征外延Ge薄膜的表面形貌、晶体质量以及应变参数,结果显示外延Ge薄膜中存在约0.2%左右的张应变,且表面平整,粗糙度为1.12 nm.此外,通过暗电流、光响应度以及3 dB带宽的测试来研究波导探测器的性能,结果表明尺寸为4μm×20μm波导探测器在-1 V的反向偏压下暗电流密度低至75 mA/cm~2,在1.55μm波长处的响应度为0.58 A/W,在-2 V的反向偏压下的3 dB带宽为5.5 GHz.     

MSM结构ZnO紫外探测器的制备与性质

采用射频磁控溅射在石英衬底上制备了c轴择优取向的ZnO薄膜,利用蚀刻技术制备了MSM结构的光导型紫外探测器。在3V偏压下,器件的暗电流小于250nA,光响应峰值在370nm,响应度是0.34A/W。其紫外(360nm)与可见光(420nm)的抑制比为4个数量级。器件的光响应时间上沿仅为20ns。     

铟锡氧化物薄膜表面等离子体损耗降低的研究

本文采用直流磁控溅射方法在普通浮法玻璃基底上制备了立方多晶铁锰矿结构的铟锡氧化物(indium tin oxide, ITO)薄膜,并对其进行了结晶性、表面粗糙度、紫外-可见吸收光谱、折射率、介电常数及霍尔效应的测试.研究了溅射时基底温度的改变对于ITO薄膜的光电、表面等离子体性质的影响.随着基底温度由100?C升高至500?C,其光学带隙(3.64—3.97eV)展宽,减少了电子带间跃迁的概率,有效降低了ITO薄膜的光学损耗.与此同时,对应ITO薄膜的载流子浓度(4.1×10~(20)-—2.48×10~(21)cm~(-3))与迁移率(24.6—32.2 cm~2·V~(-1)·s~(-1))得到提高,电学损耗明显降低.     

Air-stable ambipolar organic field effect transistors with heterojunction of pentacene and N,N'-bis(4-trifluoromethylben-zyl)perylene-3,4,9,10-tetracarboxylic diimide

Fabrication of ambipolar organic field-effect transistors (OFETs) is essential for the achievement of an organic complementary logic circuit. Ambipolar transports in OFETs with heterojunction structures are realized. We select pentacene as a P-type material and N,N'-bis(4-trifluoromethylben-zyl)perylene-3,4,9,10-tetracarboxylic diimide (PTCDI-TFB) as a n-type material in the active layer of the OFETs. The field-effect transistor shows highly air-stable ambipolar characteristics with a field-effect hole mobility of 0.18~cm²/(V.s) and field-effect electron mobility of 0.031~cm²/(V.s). Furthermore the mobility only slightly decreases after being exposed to air and remains stable even for exposure to air for more than 60 days. The high electron affinity of PTCDI-TFB and the octadecyltrichlorosilane (OTS) self-assembly monolayer between the SiO₂ gate dielectric and the organic active layer result in the observed air-stable characteristics of OFETs with high mobility. The results demonstrate that using the OTS as a modified gate insulator layer and using high electron affinity semiconductor materials are two effective methods to fabricate OFETs with air-stable characteristics and high mobility.     

Ta2O5-PMMA复合栅绝缘层对OFETs性能的影响

选用五氧化二钽（Ta₂O₅）-聚甲基丙烯酸甲酯（PMMA）复合材料作为栅绝缘层制备了并五苯有机场效应晶体管（OFETs）。通过在Ta₂O₅表面旋涂一层PMMA可以降低栅绝缘层的表面粗糙度,增大其场效应晶体管的迁移率。研究了厚度在20~60 nm范围内的PMMA对复合绝缘层表面形貌、粗糙度以及器件电学性能的影响。结果表明,当PMMA厚度为40 nm时,器件的电学性能最佳。与单一的Ta₂O₅栅绝缘层器件相比,其场效迁移率由4.2×10^-2 cm²/（V·s）提高到0.31 cm²/（V·s）;栅电压增加到-20 V时,开关电流比由2.9×10²增大到2.9×10⁵。     

Nonideal double-slope effect in organic field-effect transistors

With the development of device engineering and molecular design,organic field effect transistors(OFETs)with high mobility over 10 cm2 V-1-s-1 have been reported.However,the nonideal doubleslope effect has been frequently observed in some of these OFETs,which makes it difficult to extract the intrinsic mobility OFETs accurately,impeding the further application of them.In this review,the origin of the nonideal double-slope effect has been discussed thoroughly,with affecting factors such as contact resistance,charge trapping,disorder effects and coulombic interactions considered.According to these discussions and the understanding of the mechanism behind double-slope effect,several strategies have been proposed to realize ideal OFETs,such as doping,molecular engineering,charge trapping reduction,and contact engineering.After that,some novel devices based on the nonideal double-slope behaviors have been also introduced.     

旋涂速度对制备P3HT有机场效应晶体管性能的影响

采用溶液化的方法制备了以PMMA为绝缘层、P3HT为有源层的有机场效应晶体管.研究了P3HT有源层和PMMA绝缘层的旋涂速度对器件性能的影响.实验结果表明,当P3HT和PMMA的旋涂速度均为2 000 r/min时,器件的性能最佳.峰值场效应迁移率为6.84×10^-2 cm²·V^－1·s^－1.结果表明,选择适当的旋涂速度是一种有效提高溶液化制备有机场效应晶体管性能的方法.     

Extrinsic limiting factors of carrier transport in organic field-effect transistors

Extrinsic factors to disturb the carrier transport in pentacene field-effect transistors (FETs), as a representative of the high-mobility organic FETs (OFETs), have been comprehensively analyzed by using atomic-force-microscope potentiometry (AFMP), microscopic four-point-probe field-effect transistor (MFPP-FET) measurement, and other techniques. In the first part, by mainly using AFMP as a powerful tool to reveal the potential distribution in working OFETs, we show how and how much the formation of source/drain electrodes influences the apparent field-effect mobility both for top- and bottom-contact configurations. In the second part, we show the influence of irregular grain structures and regular grain boundaries. The films grown both at very low and high temperature ranges contain distinctive insulating parts, which make the apparent mobility very low. Within the moderate growth temperature range, the intrinsic field-effect mobility obtained by MFPP-FET measurement is proportional to the average grain size. This behavior is well explained by the polycrystalline model with the diffusion theory. According to the observations in this work, it is obvious that these extrinsic limiting factors must be carefully excluded to discuss the intrinsic mechanism of the carrier transport in OFETs.     

Identification of grain boundaries as degradation site in n‐channel organic field‐effect transistors determined via conductive atomic force microscopy

One important figure of merit for the commercial usability of organic transistors (OFETs) is their electrical stability. With the aim of identifying the microscopic location of degradation sites within a transistor channel, we have investigated the bias stress stability of OFETs by electrical measurements as well as by conductive atomic force microscopy. Air‐stable n‐channel FETs based on a N,N′‐bis(2‐ethylhexyl)‐1,7(1,6)‐dicyano‐perylene[3,4:9,10]bis (dicarboximide) were fabricated to understand the relation between the thin‐film morphology, the substrate temperature during the vacuum de position with the aim to fabricate transistors with a mobility not dominated by interface traps. The devices showed a maximum carrier mobility of (0.12 ± 0.01) cm²/V s and an on/off ratio up to 10⁷. The electrical performance as well as the bias stress behavior of the semiconductor thin‐films is significantly influenced by grain boundaries. For example, the grain boundary resistance was found to increase upon electrical stress by more than 150% (from 2 ± 0.2 GΩ to 5 ± 1.5 GΩ), while the resistance within the grains remains unchanged. (© 2016 WILEY‐VCH Verlag GmbH &Co. KGaA, Weinheim)     

Room-temperature and solution-processed vanadium oxide buffer layer for efficient charge injection in bottom-contact organic field-effect transistors

We introduce a room temperature and solution-processible vanadium oxide (VO_x) buffer layer beneath Au source/drain electrodes for bottom-contact (BC) organic field-effect transistors (OFETs). The OFETs with the VO_x buffer layer exhibited higher mobility and lower threshold voltages than the devices without a buffer layer. The hole mobility with VO_x was over 0.11 cm²/V with the BC geometry with a short channel length (10 μm), even without a surface treatment on SiO₂. The channel width normalized contact resistance was decreased from 98 kΩ cm to 23 kΩ cm with VO_x. The improved mobility and the reduced contact resistance were attributed to the enhanced continuity of pentacene grains, and the increased work function and adhesion of the Au electrodes using the VO_x buffer layer.     

有机场效应晶体管的非线性注入模型

有机场效应晶体管(Organic field effect transistor,OFET)的非线性特性是指其输出特性曲线在较低的漏极电压下出现类似于二极管的电压电流特性曲线,这种现象在有机场效应晶体管的实验研究中极为常见。Simonetti等通过引入随栅极电压变化的迁移率提出了模型并成功解释了这一现象,但实验中从器件转移特性得出的迁移率通常与栅极电压无关。本文通过引入常数迁移率对该模型进行改进,运用改进的模型研究了影响OFET非线性特性的主要因素,并对如何更加准确地获得器件参数进行了探究。     

Performance of Organic Field Effect Transistors with Self-Improved Cu/Organic Interfaces

We fabricate pentacene-based organic field effect transistors （OFETs） with Cu as source and drain （S-D） electrodes. The fabricated devices stored for ten hours under ambient atmospheric conditions exhibit superior performance compared with the as-prepared devices. The field-effect mobility increases from 0. 012 to 0.03 cm^2 V^-1 s^-1, and the threshold voltage downshifts from -14 to -9 V. The on/off current ratios are close to the order of 10^4. The improved performance of the stored devices is attributed to the formation of thin Cu oxide at the Cu electrodes/organic interfaces. These results suggest a simple and available way to optimize device properties and to reduce fabrication cost for OFETs.     

聚3-己基噻吩-b-聚十六烷氧基联烯嵌段聚合物的制备及其场效应性能

以溴代十六烷、丙炔醇为原料通过取代反应、还原重排反应制备了十六烷氧基联烯,然后以氯化(三环己基膦)镍作为催化剂,通过控制加料顺序一锅制备了聚3-己基噻吩-b-聚十六烷氧基联烯的嵌段聚合物。通过核磁共振氢谱和体积排除色谱对产物进行了表征和确证。对聚3-己基噻吩-b-聚十六烷氧基联烯嵌段聚合物的热学性能、光学性能及电学性能进行了研究。差示扫描量热法和热重分析结果表明,嵌段共聚物具有两个玻璃化转变温度及两个热分解温度,说明其具有明显相分离。以嵌段共聚物为半导体活性材料,制备了场效应晶体管器件。使用热退火对器件进行热处理,发现迁移率随退火温度的上升而提高。器件在200℃退火温度下的平均迁移率为7.03×10~(-4)cm~2·V~(-1)·s~(-1),最大迁移率为1.3×10~(-3)cm~2·V~(-1)·s~(-1),阈值电压为5.44 V。